phosphite coordination ... - ACS Publications

J . A m . Chem. SOC.1984, 106, 2907-2912

2907

Organoactinide Phosphine/Phosphite Coordination Chemistry. Facile Hydride-Induced Dealkoxylation and the Formation of Actinide Phosphinidene Complexes Michael R. Duttera,IaVictor W. Day,*lband Tobin J. Marks*la Contribution from the Department of Chemistry, Northwestern University, Evanston, Illinois 60201, the Department of Chemistry, University of Nebraska, Lincoln, Nebraska 68588, and Crystalytics Co., Lincoln, Nebraska 68501. Received October 3, 1983

Abstract: This contribution reports a study of the reaction of the organoactinide hydrides ( C P ’ ~ M H (Cp’ ~ ) ~ = $-(CH,),C,, M = Th, U) with trimethyl phosphite. Quantitative transposition of hydride and methoxide ligands occurs to yield the corresponding CP’~M(OCH,)~ complexes (synthesized independently from Cp’,MC12 and NaOCH,) and the phosphinidene-bridged methoxy complexes [Cp’2M(OCH3)]2PH.The reaction is considerably more rapid for M = U than for M = Th. The new compounds were characterized by elemental analysis, ‘H and ,lP NMR, infrared spectroscopy, magnetic susceptibility, and D 2 0 hydrolysis. The molecular structure of [Cp’,U(OCH3)I2PH has been determined by single-crystal X-ray diffraction techniques. It crystallizes in the monoclinic space group P2/n with a = 13.926 (3) A, b = 10.765 (3) A, c = 15.282 (4) A, 0 = 107.63 (2)O, and Z = 2. Full-matrix least-squares refinement of the structural parameters for the 24 independent anisotropic non-hydrogen atoms has converged to R 1 (unweighted, based on F) = 0.041 for 1677 independent absorption-corrected reflections having 20MoKa < 43” and Z > 344.The [Cp’2U(OCH3)]2PHmolecule has C, symmetry, with the pPH2- ligand lying on a crystallographic twofoid axis. The coordination geometry about each uranium ion is of the typical “pseudotetrahedral” Cp’,M(X)Y type, with U-P = 2.743 (1) A, U-0 = 2.046 (14) A, LU-P-U = 157.7 (2)O, and LU-0-C(methy1) = 178 (1)’. Evidence is presented that other >P-OR linkages react in a similar manner.

Although “soft” ligands such as phosphines and phosphites play and should give rise to isolable complexes. a unique, central role in d-element organometallic chemistry,2 the We recently reportedsd that the first organouranium phosphine parallel development of a corresponding organo-f-element phoshydrides could be prepared via the direct route of eq 1 or via an phine/phosphite chemistry has been conspicuously ~ l u g g i s h . ~ - ~ in situ U-C hydrogenolysis approach (eq 2). In both cases, a For actinides, such ligands offer the possibility of stabilizing and 4 2 ( C P ’ ~ U H , )+ ~ 2dmpe ZCp’,U(dmpe)H solubilizing complexes in low formal oxidation states. Moreover, (1) 1 simple basicity considerations6 argue that the magnitudes of acH2 tinide-phosphorus ligand bonding interactions will be nonnegligible C P ’ ~ U R ~dmpe Cp’,U(dmpe)H + 2 R H (2) 1 (1) (a) Northwestern University. (b) University of Nebraska and CrysR = CH3 or CH2Si(CH3), Cp’ = 75-(CH3)5C, talytics Co. (2) (a) Cotton, F. A.; Wilkinson, G. “Advanced Inorganic Chemistry”; 4th dmpe = (CH3)2PCH2CH2P(CH3)2

+

Ed.; Wiley-Interscience: New York, 1980; pp 87-90, 147-151. (b) Alyea, E. C.; Meek, D. W. Adu. Chem. Ser. 1982, No. 196. (c) Collman, J. P.; Hegedus, L. S. “Principles and Applications of Organotransition Metal Chemistry”; University Science Books: Mill Valley, CA, 1980; pp 54-60. (d) McAuliffe, C. A,; Levason, W. A. “Phosphorus, Arsenic, and Antimony Complexes of Transition Metals”; Elsevier: Amsterdam, 1978. (e) Stelzer, 0. Top. Phosphorus Chem. 1977, 9, 1-230. (3) (a) Marks, T. J.; Ernst, R. D. In “Comprehensive Organometallic Chemistry”; Wilkinson, G., Stone, F. G. A., Abel, E. W., Eds.; Pergamon Press: Oxford, 1982; Chapter 21. (b) Marks, T. J. Science (Washington, D.C.)1982,217,989-997. (c) Marks, T. J.; Fischer, R. D., Eds. “Organometallics of the f-Elements”;Reidel: Dordrecht, 1979. (d) Marks, T. J. Prog. Inorg. Chem. 1978, 24, 52-107; 1979, 25, 224-333. (4) Organolanthanide phosphine complexes: (a) Fischer, E. 0.;Fischer, H. J . Organomet. Chem. 1966,6, 141-148 (Yb(C5H5),P(C6H5),).(b! Marks, T. J.; Porter, R.; Kristoff, J. S.; Shriver, D. F. In ‘Nuclear Magnetic Resonance Shift Reagents”; Severs, R. E., Ed.; Academic Press: New York, 1973; pp 247-264 (Yb(CSH5),P(n-C4H9),). (c) Tilley, T. D.; Andersen, R. A,; Zalkin, A. and J . A m . Chem. SOC.1982, 104, 3725-3727 (YbL,(dmpe), E~L,(dmpe),,~, and MLz[P(n-C4H9),],where L = N[Si(CH,),],, dmpe = (CH,),PCH,CH,P(CH,),, and M = Eu or Yb). (d) Tilley, T. D.; Anersen, and R. A.; Zalkin, A. Inorg. Chem. 1983, 22, 856-859 (MCp’,(dmpe), MCp‘,(dmpm), and YbCp’,(Cl)(dmpm), where Cp’ = T’-(CH,)~C~, M = Eu or Yb, and dmpm = (CH3)2PCH2P(CH3),). (e) Schlesener, C. E.; Ellis, A. B. Organometallics 1983, 2, 529-534 (Yb(C5H5),P(C2H5),). (5) Organoactinide complexes: (a) Manriquez, J. M.; Fagan, P. J.; Marks, T. J.; Vollmer, S. H.; Day, C. S.; Day, V. W. J . A m . Chem. SOC.1979,101, 5075-5078 (Cp’2U(C1)[P(CH,),]). (b) Fagan, P. J.; Manriquez, J. M.; Marks, T. J.; Day, C. S.;Vollmer, S.H.; Day, V. W. Organometallics 1982, I , 170-180 (Cp’,U(Cl)[P(CH,),]). (c) Edwards, P. G.; Andersen, R. A,; Zalkin, A. J . A m . Chem. SOC.1981, 103, 7792-7794 (M(dmpe),Cl4, M(dm~e),(CH,)~, and M(dmpe)2(0C6H5)4. where M = Th or U). (d) Duttera, M. R.; Fagan, P. J.; Marks, T. J.; Day, V. W. Ibid. 1982, 104, 865-867 (Cp’2U(dmpe)H). (6) (a) Ikuta, S.; Kebarle, P.; Bancroft, G. M.; Chan, T.; Puddephatt, R. J. J . A m . Chem. SOC.1982, 104, 5899-5902 and references therein. (b) Puddephatt, R. J.; Bancroft, G. M.; Chan, T. Inorg. Chim. Acta 1983, 73, 83-89 and references therein. (c) Corbridge, D. E. C. “Phosphorus, An Outline of Its Chemistry, Biochemistry, and Technology”; Elsevier: Amsterdam, 1978; p 156.

0002-7863/84/1506-2907$01.50/0

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-

tetravalent starting material is converted into a phosphine-stabilized trivalent product. Complex 1 displays rich and vigorous reactivity patterns with CO, olefins, nitrogen and oxygen atom donors, and a variety of other reagents. These will be discussed in detail el~ewhere.’~ Phosphites are generally viewed as being stronger K acceptors than Thus, the possibility of further stabilizing low actinide formal oxidation states and/or of observing ligand reactivity modes beyond conventional (2) 7’-P donor-acceptor interactions2,s (e.g., 39 and 4’O) has prompted studies analogous OR

0 M-ZPIOR),

2

IOR, I 1 M-M

0-P

O,R [[

M-P O ‘R

3

4

to eq 1 and 2 with phosphite ligands. In the present contribution we report7ba chemical, spectroscopic, and structural investigation of this reaction, the course of which represents, to our knowledge, an unprecedented mode of reactivity for a d- or f-element hydride (7) (a) Duttera, M. R.; Marks, T. J., manuscript in preparation. (b) Presented in part at the XI International Conference on Organometallic Chemistry, Pine Mountain, GA, Oct 10-14, 1983, Abstract 83. (8) Reference 6c, pp 155-166, 206-212. (9) (a) Towle, D. K.; Landon, S. J.; Brill, T. B.; Tulip T. H. Organometallics 1982, I , 295-301 and references therein. (b) Goh, L.-Y.; DAniello, M. J., Jr.; Slater, S.;Muetterties, E. L.; Tavanaiepour, I.; Chang, M. I.; Fredrich, M. F.; Day, V. W. Inorg. Chem. 1979, 18, 192-197. (c) King, R. B.; Dieffenbach, S. a. Ibid. 1979, 18, 63-68. (d) Haines, R. J.; Dupreez, A. L.; Marais, I. L. J . Organornet. Chem. 1971, 28, 97-104, 405-413. (10) Burch, R. R.; Muetterties, E. L.; Thompson, M. R.; Day, V. W. Organometallics 1983, 2, 474-478.

0 1984 American Chemical Society

2908

J . Am. Chem. SOC.,Vol. 106, No. 10, 1984

with trialkyl phosphites. We also report t h e synthesis a n d characterization by single-crystal X - r a y diffraction of a phosphinidene-bridged binuclear organoactinide which results from this chemistry.

Experimental Section Synthetic Methods. All organoactinides were handled in Schlenk glassware on a dual-manifold Schlenk line or interfaced to a high-vacuum (lo-’ torr) system. Solid transfers were accomplished in a Vacuum Atmospheres Corp. glovebox equipped with an atmosphere purification system, maintained under a nitrogen atmosphere. Argon (Matheson, prepurified), nitrogen (Matheson, prepurified), and hydrogen (Linde) were purified by passage through sequential columns of MnO and Davison 4A molecular sieves. Reactions with gases were carried out on the high-vacuum line using a mercury-filled manometer. The starting materials CP’,T~(CH,)~,Cp’,U(CH3),, (Cp’2ThH2)2,and (Cp’+JH,), were prepared as described elsewhere.” Trimethyl phosphite and triisopropyl phosphite (Strem) were dried by refluxing over sodium and then distilling under reduced pressure. The ligands P(C,H,)(OCH,), (Organometallics, Inc.) and P(C,Hs),(OCH3) (Strem) were stirred over N a / K alloy overnight, distilled under vacuum, and freeze-pumpthaw degassed. Measured quantities of these reagents were transferred via a 250-pL gastight syringe. Solvents were thoroughly washed, dried, and deoxygenated in a manner appropriate to each and were then distilled under nitrogen. They were stored over appropriate drying agents in evacuated storage bulbs on the vacuum line. Analytical Methods. Proton and phosphorus N M R spectra were obtained on a JEOL FX 270 (FT, ‘H 269.65 MHz; 109.16 MHz), JEOL FX 90Q (m,‘H 89.55 MHz; 31P36.19 MHz), or Varian EM-390 (CW, 90 MHz) instrument. Chemical shifts are referenced relative to internal Me& or external 85% H3PO4. Samples were prepared either on a high-vacuum line or in the glovebox. Deuterated aromatic solvents were dried overnight over N a / K alloy and were degassed by freezepump-thaw cycles on a high-vacuum line. The magnetic susceptibility of [Cp’,U(OCH3)],PH was measured by the Evans method.’, Infrared spectra were recorded on a Perkin-Elmer 599B spectrophotometer using Nujol mulls sandwiched between KBr plates in an 0-ring-sealed airtight holder. Spectra were calibrated with polystyrene film. Elemental analyses were performed by Dornis and Kolbe Mikroanalytisches Laboratorium, Miilheim, West Germany. Synthesis of [Cp’,U(OCH,)],PH (5). In a 30-mL reaction flask in the glovebox were placed 2.00 g (3.71 mmol) of Cp’,U(CH3), and 0.15 mL (1.27 mmol) of P(OCH,),. The reaction apparatus was then attached to the vacuum line, the reagents were cooled to -196 “C, and 15 mL of dry, degassed pentane was distilled into the reaction flask. After warming to room temperature, the resulting solution was filtered and an atmosphere of H 2 admitted. After stirring for 6 h at room temperature, the solution had become dark green. The volume was next reduced to 5 mL and the solution slowly cooled to -78 OC. Cold filtration yielded a dark green, microcrystalline solid, which was washed with 3 X 3 mL portions of filtrate pentane by Soxhlet extraction. The volatile materials were then removed in vacuo and the product was further dried overnight under high vacuum; yield 0.65 g (42% based upon P(OCH,),) of [Cp’,U(OCH,)],PH as dark green microcrystals. IR (Nujol mull): 2193 m, 1262 vw, 1100 vs, 1022 s, 950 w, 802 w, 563 w, 422 s cm-I. Anal. Calcd for C42H6702PU2:c, 45.41; H, 6.08; P, 2.79. Found: C , 45.89; H, 6.11; P, 2.58. Synthesis of [Cp’,Th(OCH,)],PH (6). This reaction was carried out in a manner analogous to the uranium system above, using 1 .OO g (1.88 mmol) of Cp’,Th(CH,), and 0.078 mL (0.66 mmol) of P(OCH3), in.10 mL of dry, deoxygenated pentane. As assessed by ‘H NMR, this reaction required 37 h to reach completion. Workup as above gave 0.315 g (43% based upon P(OCH,),) of [Cp’,Th(OCH,)],PH as a light yellow, microcrystalline solid. IR (Nujol mull): 2200 m, 1105 vs, 1022 m, 800 w, 580 s cm-I. Anal. Calcd for C4,H6,02PTh: C, 45.90; H, 6.14; P, 2.82. Found: C, 45.83; H , 6.17; P, 2.93. Synthesis of Cp’,U(OCH3), (7). In the drybox, a 30-mL reaction vessel was charged with 0.300 g (0.518 mmol) of Cp’,UCI, and 0.065 g (1.203 mmol) of NaOCH,. The reaction apparatus was then attached to a vacuum line, the reaction flask was cooled to -78 OC, and 10 mL of dry, degassed 1,2-dimethoxyethanewas distilled into the reactants in vacuo. An atmosphere of argon was admitted and the red slurry allowed to warm to room temperature. Next the flask was lowered into a 70 OC oil bath, and the reaction was stirred for 14 h at this temperature. The (1 1 ) Fagan, P. J.; Manriquez, J. M.; Maatta, E. A,; Seyam, A. M.; Marks, T. J. J . Am. Chem. SOC.1981, 103, 6650-6667. (12) (a) Ostfeld, D.; Cohen, I. A. J . Chem. Educ. 1972, 49, 829. (b) Evans, D. F. J . Chem. SOC.1959, 2003-2005.

Duttera, Day, and Marks oil bath was then removed and the solvent stripped under high vacuum to yield a yellow-green residue. The residue was dried in vacuo for 1.5 h, after which time it was taken up in 3 mL of dry, degassed pentane. The pentane solution was next cooled to -78 OC for 10 min and coldfiltered to yield a yellow-green filtrate. Slow evaporation of the filtrate and vacuum drying for 2 h yielded 0.130 g (45%) of Cp’,U(OCH,), as a yellow-green, microcrystalline solid. IR (Nujol mull): 11 13 vs, 1088 vs, 1020 w, 800 w cm-l. Anal. Calcd for C22H3602U:c, 46.31; H , 6.36. Found: C, 46.26; H, 6.29. Synthesis of CpiTh(OCH3), (8). In a manner analogous to that above, Cp’,Th(OCH,), was prepared in 51% yield as colorless microcrystals. IR (Nujol mull): 1123 vs, 1083 vs, 1020 w, 800 w cm-I. Anal. Calcd for C,,H,,O,Th: C , 46.82; H, 6.43. Found: C, 46.69; H, 6.42. Study of the (Cp’,ThH,), + P(OCH3), Reaction by Toepler Pump. In the glovebox, 0.400 g (0.396 mmol) of (Cp’,ThH,), was placed in a reaction tube that could be sealed with a Kontes high-vacuum Teflon valve. The tube was next connected to the high-vacuum line, and 5 mL of dry, degassed toluene was distilled into the tube, which had been cooled to -196 “C. Then 0.037 mL (0.314 mmol) of P(OCH,),, which was placed in a separate vessel on the vacuum line, was vacuum transferred onto the frozen solution. The tube was then closed and the reaction mixture stirred for 5 days (a time judged by the N M R studies to be adequate for completion) in the dark at room temperature. The evolved gases (0.621 mmol, noncondensable at -196 “C) were then removed by Toepler pump and passed through a CuO catalyst at 280 ‘C. Combustion was complete at this low temperature and the combustion product was involatile at -78 OC. These results indicate the formation of H 2 in 98% of the theoretical yield given by eq 6. X-ray Crystallographic StudyI3 of [Cp’,U(OCH3)]2PH(5). Dark green crystals of 5 suitable for diffraction analysis were grown by allowing a saturated pentane solution of Cp’,U(CH,), and 0.35 equiv of P(OCH,), to stand under an H, atmosphere at room temperature for 4 days. They are at 20 f 1 OC monoclinic with a = 13.926 (3) A, b = 10.765 (3) A, c = 15.282 (4) A, p = 107.63 (2)”, V = 2183 (1) A3, and Z = 2 [ka(Mo Ka)’4a = 7.09 mm“; dald = 1.690 g ~ m - ~ ]The . systematically absent reflections in the diffraction pattern were those required by the centrosymmetric space group P2/n (an alternate setting of P2/c-G,,, No. 13)15”or the noncentrosymmetric space group Pn (an alternate setting of Pc-C:, No. 7).’5b The choice of the centrosymmetric space group was fully supported by the various statistical indicators based on normalized structure factors as well as by all stages of the subsequent structure determination and refinement. Intensity measurements were made on a Nicolet P1 autodiffractometer using full (1.00” wide) w scans and graphite-monochromated Mo K a radiation for a specimen having the shape of a rectangular parallelepiped with dimensions of 0.15 X 0.60 X 0.75 mm. This crystal was sealed under N2 in a thin-walled glass capillary and mounted on a goniometer with its second longest edge nearly parallel to the q5 axis of the diffractometer. A total of 2513 independent reflections having 28nrOK,< 43.0’ (the equivalent of 0.50 limiting Cu K a spheres) were measured with a scanning rate of 6” m i d . The data collection and reduction procedures which were used are described elsewhere,16 the scan width and step-off for background measurements were both l.OOo, and the ratio of total background counting time to net scanning time was 0.50. The intensity data were corrected empirically for absorption effects using ic. scans for an intense reflection having 28 = 10.0” (the relative transmission factors ranged from 0.09 to 1.00). The structure was solved by using the “heavy-atom” technique. Unit-weighted anisotropic full-matrix least-squares refinement of the parameters for the U and P atoms converged to R , (unweighted, based on F)I’ = 0.109 and R2 (weighted based on F)” = 0.154 for 1677 (13) See paragraph at end of paper regarding supplementary material. (14) (a) ‘International Tables for X-ray Crystallography”;Kynoch Press: Birmingham, England, 1974; Vol. IV, pp 55-66. (b) Reference 14a pp 99-101. (c) Reference 14a pp 149-151. ( 15) (a) “International Tables for X-Ray Crystallography”;Kynoch Press: Birmingham, England, 1969; Vol. I, p 97. (b) Reference 15a p 85. (16) Fagan, P. J.; Manriquez, J. M.; Vollmer, S. H.; Day, C. S.; Day, V. W.; Marks, T. J. J . Am. Chem. SOC.1981, 103, 2206-2218. (17) The R values are defined as RI =

XIlFol- l ~ c l l / m o l

and Rz = iCw(lFJ - l ~ ~ l ~ z / ~ ~ l ~ ~ l ~ ~ ” *

where w is the weight given each reflection. The function minimized is

Zw(lF0l - KlFc1)2 where K is the scale factor.

J. Am. Chem. SOC., Vol. 106, No. 10, 1984 2909

Organoactinide PhosphinelPhosphite Chemistry Table I.

‘ H and 31PN M R

Spectral Data for New

complex

,

{U[n5-(CH,),c5I [ OCH, 1) PH {ThlnS-(CH,),C,I ? [OCH, l j , P H

nuclei

~5-lCH,),C,

other

’H H

--2.98(60 H , S , I w = 17 Hz) 2.21 (60 H, s)

P ‘H ‘H

-0.72 (30 H, S , IW 2.11 ( 3 0 H, s)

75.5 (6 H, S , l~ = 1 2 Hz. U-OCH, 1 3.84 (6 H, S, Th-OCH,), 0.54 I1 H, d , J = 114.7 Hz, Th-P-H) 74.0 (d, J = 114.7 Hz, P-11) 17.5 16 H. S , I w =2.5 Hz. U-OCH, ) 3.79 (6 H, S , Th-OCH,)

3’

U [ T ~ - ( C H , ) ~ IC,[OCH, , I, Th[ri5-(CH,),C,], [ OCH, l 2

7 Hz)

’

a Recorded in C, D, at 30 “C. Chemical shifts are reported in parts per million from Me,Si for H spectra and from 85’); H,PO, for 3 1 P s = sinFlct, d = doublet, l u = line width at half-maximum spectra.

independent absorption-corrected reflections having 20MoKa < 43’ and I > 3 4 . Inclusions of the remaining 22 non-hydrogen atoms into the model with isotropic thermal parameters gave RI = 0.057 and R2 = 0.068 for 1677 reflections. The final cycles of empirically weighted’* full-matrix least-squares refinement which utilized anisotropic thermal parameters for all nonhydrogen atoms gave R ,= 0.041 and R2 = 0.053 for 1677 independent absorption-corrected reflections having I > 3a(I). Since a careful examination of final IFo] and lFcl values indicated the absence of extinction effects, extinction corrections were not made. The three highest peaks (0.83-1.38 e A3) in a difference Fourier calculated at this point were within 1.27 of the U atom; the remaining peaks did not correspond to structurally reasonable positions for hydrogen atoms of 5. All structure factor calculations employed recent tabulations of atomic form factors’4band anomalous dispersion correctionsi“ to the scattering factors of the U and P atoms. All calculations were performed on a Data General Eclipse-S200 computer equipped with 64K of 16-bit words, a floating-point processor for 32- and 64-bit arithmetic, and versions of the Nicolet EXTL interactive crystallographic software package as modified at Crystalytics Co.

a

d

b

Results Phosphite-Actinide Hydride Reactions. In an initial attempt to study analogues of eq 1 and 2 using trialkyl phosphites as ligands, the reactions of Cp’,U(CH,), and Cp’,Th(CH3), with P(OCH,), were investigated under an H, atmosphere (eq 3 and 4). Under conditions of excess H z and n > 1, each reaction yields Cp’,U(CH3), Cp’,Th(CH,),

+ nP(OCH,), + nP(OCH,),

-+ -+ H2

H2

5

7

(3)

6

8

(4)

‘““‘“““4 ‘““‘“6 .‘60“pM

two products, which can be separated by fractional crystallization (7 and 8 are extremely soluble in pentane). As is typical of U(1V) organometallic^,^^^^ the ‘H N M R spectra of 5 and 7 exhibit substantial isotropic shifts (Table I). Thus, compound 5 displays singlet ‘H resonances at -2.98 and 75.5 ppm in an intensity ratio of 1O:l (Figure l), while 7 exhibits resonances at -0.72 and 17.5 ppm in an intensity ratio of 5:l. The relatively narrow line widths are suggestive of U(IV),3,5b*dJ1 and in each case the more intense resonance is in the chemical shift region generally expected for a U1V[q5-(CH3),C5],moiety. Although elemental analysis indicates the presence of phosphorus in 5 (but not 7), it has not been possible to observe a signal in the 3 i PN M R spectrum. This is not an unexpected observation for phosphorus bound directly to ~ r a n i u m and , ~ apparently ,lP spin-lattice relaxation times are rather short in such circumstances. Further information on the structures of 5 and 7 derives from infrared spectroscopic and chemical studies. Both complexes exhibit strong, infrared-active transitions in the 1100-cm-I region which are not assignable to a UCp’, residue.” Rather, these features are assignable to a C - O stretching mode as in a uranium methoxide c ~ m p l e x . ’ ~In addition, the infrared spectrum of 5 (18) Empirical weights were calculated from the equation 3

u = ZU,lFoI” = 0

the

2.53 + 7.10 x 10-31~~1 - 1.28 x 10-51~~12 + 1.64 x 10-71~~13 being coefficients derived from the least-squares fitting of the curve

(I,

3

llFol - IFEll

=

pnlFal”

where the F, values were calculated from the fully refined model using unit weighting and an I > 341) rejection criterion.

Figure 1. (a) 89.55-MHz ’H N M R spectrum of (U[qS-(CH3)5CS]2(OCH,)),PH (5) in C6D6at 30 OC (s denotes residual proton absorption of solvent and i denotes a small impurity peak which is less than 3% in integrated intensity relative to (CH3)5C5absorption). Peak at 0 ppm is due to Me&. (b) 89.55-MHz ’H N M R spectrum of (Th[qS(CH3)5C5]2(OCH3))2PH ( 6 ) . Asterisks denote signals assignable to the P-H proton. The impurity (i) is due to the presence of residual Th[q5-(CH3)sC5]2(OCH3)2 (7). Resonance at 0 ppm is due to Me4Si.

242.5

245.5

PPM

Figure 2. 109.16-MHz Proton-coupled ” P N M R spectrum resulting from deoxygenated D,O hydrolysis of a C6D6 solution of 5.

displays a non-UCp’, transition at 2193 cm-’, which is displaced to 1575 cm-I when eq 3 is carried out under DZ.This vibration (19) (a) Cuellar, E. A,; Miller, S. S.; Marks, T. J.; Weitz, E. J . Am. Chem. SOC.1983, 105, 4580-4589. (b) Cuellar, E. A,; Marks, T. J. Znorg. Chem. 1981,20, 2129-2137. (c) Bradley, D. C.; Mehrotra, R. C.; Gaur, D. P. “Metal Alkoxides”;Academic Press: New York, 1978; pp 116-134. (d) Bradley, D. C. Adu. Inorg. Chem. Rudiochem. 1972, 15, 259-322. (e) Bradley, D. C.; Fisher, K. J. MTP Znt. Rev. Sci.: Inorg. Chem., Ser. One 1972, 5 , 65-78.

2910 J. A m . Chem. SOC.,Vol. 106, No. 10, 1984 is reasonably assigned to a P-H stretching modez0(up-H/~p-D= 1.39). When complex 5 is decomposed with deoxygenated HzO, = 189.2 Hz the 31PN M R spectrum reveals PH321(6 -239, lJp-H (quartet)) as the only phosphorus-containing product. Hydrolysis of 5 with a trace of DzO produces a quintet (’Jp-D= 30 Hz) in the 31P(1H) N M R spectrum and a doublet of quintets (lJp-H= 189.2 Hz) in the undecoupled spectrum. This information is illustrated in Figure 2. These latter results are consistent with the formation of PDZH.’I Isotopic exchange of P H 3 with DzO is known to be slow under conditions such as these.2z The magnetic properties of 5 were investigated in solution by the Evans technique.Iz At 30 “C, the average of three meaemu mol-], pefl= surements yields xM = 10 100 (3500) X 2.42 (44) p B (296 K) per uranium atom. These results, although not definitive, are in best agreement with a U(1V) formulation for 5, as opposed to U(II1) or U(II1)-U(1V) mixed valency.23 In regard to eq 4, the ‘H N M R spectrum of thorium complex 6 (Figure 1) exhibits singlet resonances at 6 2.21 (60 H) and 3.84 (6 H), which are assignable to $-(CH3)5Cs” and OCH3I9ligands, respectively. Furthermore, a doublet at 6 0.54 (J = 114.7 Hz, 1 H ) is also evident and can be assigned to a P-H functionality.2’ An analogous resonance could not be unambiguously located in the case of 5. The low magnitude of this one-bond P-H coupling constant indicates the presence of unusually electropositive substituents and/or of unusual valence angles about the phosphorus atom.21 The 31P(1HJ N M R spectrum of 6 consists of a singlet at 6 74.0 that splits into a doublet ( J = 114.7 Hz) in the absence of heteronuclear decoupling. Selective-decoupling experiments indicate that this phosphorus unit is coupled to the proton resonance at 6 0.54. The ‘H N M R spectrum of 8 consists of singlet resonances at 6 2.11 (30 H ) and at 6 3.79 (6 H), assignable to V ~ - ( C H , ) ~and C ~OCH, groups, respectively. The infrared spectra of the pairs 5,6 and 7,8 are essentially superimposable. At this juncture, the chemical and spectroscopic results strongly suggested that 7 and 8 were bis(pentamethylcyclopentadieny1)actinide(1V) bis(methoxides) (9). This assertion was verified by

d ’OCH,

@OCH3

9, M = Th, ‘-I

the synthesis and characterization of authentic samples. Methathesis as shown in eq 5 proved to be the most stratightforward Cp’zMC12 + 2NaOCH3

DME

CP’~M(OCH~ +)2NaC1 ~ (5) 7, M = U 8, M = Th

14h

route, while the reaction of methanol with the corresponding hydrides proved to be far less clean. The identity of 5 and 6 does not follow unambiguously from the data at hand, although the presence of a bridging P-H functionality (e.g., 10) as well as H

I

21

P M‘

’ IO

(20) (a) Corbridge, D. E. C. Top. Phosphorus Chem. 1969,6, 251-255. (b) Bellamy, L. .I. ‘The Infra-red Spectra of Complex Molecules”, 3rd ed.; Chapman and Hall: London, 1975; pp 357-358. (21) (a) Brazier, J. F.; Houalla, D.; Loenig, M.; Wolf, R. Top. Phosphorus Chem. 1976,8, 99-192. (b) Mavel, G. Annu. Rep. N M R Spectrosc. 1973, 5B,1-441. (c) Crutchfield, M. M.; Dungan, C. H.; Letcher, J. H.; Mark, V.; Van Wazer, J. R. Top. Phosphorus Chem. 1967, 5, 1-489. (22) (a) Weston, R. E.; Bigeleisen, J. J . Am. Chem. SOC. 1954, 76, 3074-3078. (b) With very larrge excesses of D20, we find that there is only ca. 50% exchange after 18 h. (23) (a) Kanellakopulos, B. In ref 3c, Chapter 1. (b) Marks, T. J.; Seyam, A. M.; Kolb, J. R. J . Am. Chem. SOC.1973, 95, 5529-5539. (c) For Cp’,U(dmpe)(H), xM = 5120 X IO” emu mol-’ and weft = 3.47 pB.5d

Duttera, Day, and Marks

h b 2

Figure 3. Perspective ORTEP plots showing two different views of the solid-state structure for the (U[~S-(CH3)5C5]2(0CH3)~2PH molecule (5). The uranium and phosphorus atoms are represented by thermal vibration ellipsoids drawn to encompass 50% of the electron density; all carbon and oxygen atoms are represented by arbitrarily sized spheres for purposes of clarity. Hydrogen atoms were not located and are not shown. Atoms labeled with primes are related to those labeled without primes by the in the unit cell which crystallographic C, axis located at y, passes through the PH2- ligand. Table 11. Atomic Coordinates for Non-Hydrogen A t o m \ in Crystalline {L‘[ qS-tCH, J 5 C S] (OCH, )},pH 15Ja atom typeb

I0 3 ~ 207.06 14) 250.0 (-)‘ 101 11) 25 ( 2 ) 184 12) 142 12) 53 ( 2 ) 52 ( 2 ) 134 ( 2 ) 272 ( 2 ) 175 ( 3 ) -14 ( 3 ) -29 (3) 131 ( 4 ) 394 ( 1 ) 328 (2) 305 11) 352 (1j 405 ( 1 ) 461 (2) 300 13) 236 ( 2 ) 367 13) 481 (2)

I05

I 032

236.04 (5) 285.3 16) 100 11) 5 (2) 469 (2) 4 7 8 12) 4 0 2 (2) 349 12) 391 12) 543 ( 3 ) 575 (2) 400 14) 269 ( 3 ) 357 (4) 1 2 8 (2) 35 (2) 6 3 (2) 173 (2) 213 (2) 125 (4) -82 (3) -8 15) 234 (4) 325 ( 3 )

410.26 (4) 250.0 (-)‘ 366 (1) 337 (2) 484 12) 392 11) 366 (1) 4 5 0 12) 519 ( 1 ) 540 ( 4 ) 3 2 8 (3) 269 ( 2 ) 465 (5) 617 12) 446 (1) 452 11) 535 11) 569 ( 1 ) 514 12) 381 (2) 400 (3) 579 (4) 667 12) 527 (3)

a Number5 in parentheses are the estimated standard deviations Atoms are labeled in agreement in the last sipificant digit. This is a symmetry-required value and is therewith 1 igure 3 . fore listed without an estimated standard deviation.

methoxide and q5-(CH3),CSligands is implicated. For these reasons, a diffraction investigation of the molecular structure of 5 was undertaken. Molecular Structure of (U[(CH3),C5]2(OCH3)]zPH (5). The X-ray structural analysis reveals that single crystals of 5 are

J . A m . Chem. SOC.,Vol. 106. No. 10, 1984 291 1

Organoactinide Phosphinelphosphite Chemistry Table IV. h n d Lengths I x) and Angles Idcg) in Coordination (;roups of { ~ [ ~ 5 - ~ C l ~ ~ ) ~ C ~ ] * ((5 ~) c ‘ ~ l ~ J ~ * P t ~ a oaratneterb

Lengths 2.046 ( 1 4 ) L-Cpa, U-c‘,,, 2.743 ( I ) U-CPa3 L’-Cpa4 2.483 (-1 U-C,,, 2.462 i-) U-(‘pb, U-C,,,, 1.44 ( 3 ) U-C;;;

U-0 L-P

u-c,, “-C,b

0-C

u...u

paraiiieterb

value

U-(Ipbi

2.80 ( 2 ) 2.75 ( 2 ) 2.71 ( 2 ) 2.70 ( 2 ) 2.76 ( 2 ) 2.76 ( 2 ) 2.70 ( 2 ) 2.72 ( 2 ) 2.73 ( 2 ) 2.75 ( 2 )

C,,UO C,hUO Ci,-UP C&LP

105.0 (-) 103.5 (-1 107.1 (-) 103 6 (-)

UOC

178 ( 1 )

U-(‘Pb4

5.382 i 1 J

’

value

A np I C s

PUO

100.0 (41

CgaUCgb

133.1 (-1

UPU’

157.7 ( 2 )

placements. The least-squares mean planes of these five-membered rings intersect that of the of the “equatorial girdle” defined by U, 0, and P27cin dihedral angles of 22.8 and 20.8’. The two five-carbon ring mean and that of the “equatorial girdlex2” intersect the mean plane defined by U and the two respectively) five-carbon ring centers of gravity27d(c,,and c&, in dihedral angles ranging from 88.3 to 89.4’. In regard to the u bonded ligands, the 2.743 (1) A U-P bond length in 5 is significantly shorter than the formally coordinatecovalent U-P bond lengths of 3.21 1 (8) and 3.092 (8) A in trivalent, formally 9-coordinate C ~ ’ ~ U ( d m p e )and H ~ 3.104 ~ (6) A in tetraualent, formally 8-coordinate U(dmpe)2(OC&~)4.~~ For these coordination numbers, differences in U(II1) and U(IV) ionic radii28should be on the order of ca. 0.12 A.5b,29The significantly shorter U-P distance in 5 may reflect the lower phosphorus coordination number as well as phosphorus-to-uranium x donation (and multiple-bond character) analogous to that proposed31for transition-metal dialkylamides. The rather obtuse U-P-U bond angle of 157.7 (2)’ in 5 is significantly larger than the Mn-P-Mn angle of 138 ( 1 ) O in the only other well-characterized w-phosphinidene complex, [CpMn(C0)2]2PC6H5(1l).,’ The large angle

a Numbers in parentheses are the estimated standard deviations

in the last significant digit. with I igure 3.

Atoms are labeled in agreement P

composed of dinuclear (U[aS-(CH3),C5],(OCH,)),PH molecules like that shown in Figure 3. The bridging p-PH2- ligand in 5 lies on a crystallographic twofold axis at 1/4, y , 1/4 in the unit cell. The U(IV) ion in each structurally equivalent half of the molecule adopts the familiar “pseudotetrahedral” bent-sandwich Cp’,M(X)Y actinide coordination g e ~ m e t r y , ~by* ~being s ~ ~a bonded to two (CH3)5C5-ligands and u bonded to a terminal OCH,- ligand and the bridging PH2- ligand. Final atomic coordinates and anisotropic thermal parameters for the non-hydrogen atoms of 5 are given in Tables I1 and 111,13 respectively. Bond lengths and angles in the coordination groups and the (CH3)J5- ligands of 5 are given with estimated standard deviations in Tables IV and V,13 respectively. The labeling scheme is shown in Figure 3. The structural parameters in Table IV for the coordination groups of 5 are typical for a formally 8-coordinate Cp’,U(X)Y specie^:^.^,^^ U-C(cyclopentadienyl), 2.74 (2, 3, 6, 10) A,25U-0, 2.046 (14) LCga-U-Cgb,26 133.1’; Lp-u-0, 100.0 (4)’; LC,-U-O, 104.3 (-, 8, 8, 2)’, and LC,-U-P, 105.3 (-, 18, 18, 2)’. The metrical parameters for the (CH3)&,- ligands are also une~ceptional:~*~**~ ring C-C, 1.38 (3, 3, 8, 10) A; ring-to-methyl C-C, 1.54 (4, 4, 7, 10) A; L ring C-C-C, 108 (2, 2, 5 , 10)’; L ring-to-methyl C-C-C, 126 (2, 4, 12, 20)O. The five-membered carbon rings of both independent (CH3),CS-ligands are coplanar to within 0.03 A,27a,bwith the methyl groups displaced by 0.01-0.32 A from the respective five-carbon least-squares mean plane in a direction away from the U atom. In each Cp’ ligand, the methyl groups nearest the equatorial girdle (Cmaland Cmas in ligand a and Cmb4in ligand b) have some of the largest disI&;

(24) (a) Bruno, J. W.; Marks, T. J.; Day, V . W. J . Organomer. Chem. 1983, 250, 237-246. (b) Bruno, J. W.; Marks, T. J.; Day, V. W. J . Am. Chem. Sot. 1982, 104, 7357-7360. (c) Marks, T. J.; Manriquez, J. M.; Fagan, P. J.; Day, V . W.; Day, C. S.; Vollmer, S . H. ACS Symp. Ser. 1980, NO. 131, 1-29. (25) The first number in parentheses following an averaged value of a bond length or angle is the root-mean-square estimated standard deviation of an individual datum. The second and third numbers, when given, are the average and maximum deviations from the averaged value, respectively. The fourth number represents the number of individual measurements which are included in the average value. (26) c,, and c,b refer to the centers of gravity for the five-carbon rings of (CH3),C,- ligands a and b, respectively. (27) The least-squares mean planes for the fallowing groups of atoms in U[Cp’,(OCH3)12PH (5) are defined by the equation ax bY cZ = d , whsre X , Y , and Z are orthogonal coordinates measured in angstroms along 2, b, and Z*, respectively, of the unit cell: (a) C,,,, Cp2, CPa3,Cpa4,and CpaS (coplanar to within 0.01 A): a = 0.5512, b = -0.7652, c = -0.3328, d = -4.704; (b) Cpbl, cpb,, Cpbl,CpM.and CpbJ(coplanar to within 0.03 A): a = 0.7878, b = -0.5222, c = 0.3265, d = 5.0618; (c) U, P, and 0: a = 0.7204, b = -0.6934, c = 0.0163, d , = 0.3060; (d) U, C,,,26 and Cgb:26a = 0.5875, b = 0.6137, c = -0.5274, d = 0.3280.

+

+

(CO)e(Csh,)M“/

‘Mn(C5H5)(CO\2

11

in the present case may reflect large, repulsive CP’~U(OCH,)CP’~U(OCH,)nonbonded interactions and/or the less directed character of a more polar metal-ligand bonding situation. However, in view of the foregoing discussion,the larger angle could also conceivably reflect a bonding (sp3 sp2). The U-0 distance of 2.046 (14) 8. in 5 is in favorable agreement with the value of 2.056 (13) A reported for the terminal Somewhat alkoxide of [U(q3-C3H,)2(O-i-C3H7)(p-O-i-C3H7)]2.3h longer are the u(Iv)-0 distances reported for U(dmpe)2(OC6H,), (2.17 (1) U(catecholate), (2.375 (13) A),32b U(hexaand U[q5-1,3fluoroacet~nylpyrazolide)~ (2.237 (8) [(CH3)~Si12C~H3J,[O-2,6-(CH3)2C6H,1, (2.120 (61%2.109 (6) A).32dThe rather large U-0-C(methy1) angle of 178 (1)’ in 5 is comparable to that in the aforementioned U(1V) allyl alk178.0 (lo)’, and in a number of early transition-metal a l k o x i d e ~ . ’ ~ ~The ” ~ ~angle ~ in the above silyl-substituted cyclopentadienyl aryl oxide is somewhat smaller at 157’.32d Such structural features are arguably a consequence of oxygen-to-metal a donation and rather shallow potential surfaces for LU-0-C deformation. There are no intermolecular nonbonded contacts which are significantlyshorter than the sum of the appropriate van der Waals radii.34 Reaction Mechanism and Stoichiometry. The foregoing chemical discussion provides only circumstantial evidence for the intermediacy of an actinide hydride in eq 3 and 4. More conclusive evidence is provided by the observation that, in the absence of H,,

-

(28) Shannon, R. D. Acta Crystallogr., Secr. .4 1976, A32, 751-767. (29) (a) Raymond, K. N.; Eigenbrot, C. W., Jr. Acc. Chem. Res. 1980, 13, 276-283. (b) Raymond, K. N. In ref 3c, Chapter 8. (c) Baker, E. C.; Halstead, G. W.; Raymond, K. N. Struct. Bonding (Berlin) 1976, 25, 23-68. (30) Huttner, G.; Muller, H. D.; Frank, A,; Lorenz, H. Angew. Chem., Int. Ed. Engl. 1975, 14, 705-706. Note Added in Proof See also: Huttner, G.; Borm, J.; Zsolnai, L. J . Urganomer. Chem., 1984, 263, C33-C36 ([Cr(CO)512P(t-C,H,)). (31) (a) Eller, P. J.; Bradley, D. C.; Hursthouse, M. B.; Meek, D. W. Coord. Chem. Reo. 1977, 24, 1-95. (b) For an alternative interpretation of the M-N bond lengths in f-element dialkylamides, see ref 29a. (32) (a) Brunelli, M.; Perego, G.; Lugli, G.; Mazzei, A. J . Chem. Soc., Dalton Trans. 1979,861-868. (b) Sofen, S . R.; Abu-Dari, K.; Freyberg, D. P.; Raymond, K. N. J . Am. Chem. Sot. 1978,100, 7882-7887. (c) Volz, K.; Zalkin, A,; Templeton, D. H. Inorg. Chem. 1976, 1 5 , 1827-1831. (d) Hunter, W. E.; Atwood, J. L. Proc. First Int. Conf. Chem. Tech. Lanthanides, Actinides; Venice, Sept 5-10, 1983, Abstract A50. (33) Huffman, J. C.; Moloy, K. G.; Marsella, J. A.; Caulton, K . G. J . Am. Chem. Sot. 1980, 102, 3009-3014 and references therein. (34) Pauling, L. “The Nature of the Chemical Bond”, 3rd ed.; Cornell University Press: Ithaca, NY, 1960; p 260.

2912 J. Am. Chem. SOC.,Vol. 106, No. 10, 1984

Duttera, Day, and Marks

there is no detectable reaction between Cp’,U(CH,), or Cp’,Th(CH,), and P(OCH3),. Furthermore, in N M R tube reactions both (Cp’,UH2), and (Cp’,ThH2), were found to react with P(OCH,), as shown in eq 3 and 4, producing the product pairs 5,7 and 6,8, respectively. In the case of uranium, the reaction is complete within 1 h, whereas the thorium hydride reaction requires anywhere from one to several days, depending on reactant concentrations. As regards reaction stoichiometry, a Toepler pump quantitation of evolved gases in the thorium hydride reaction (see Experimental Section for details) verifies the stoichiometry shown in eq (6)-98% of the theoretical yield of H, is produced. Com-

-

S(Cp’,ThH,), + 4P(OCH3)3 2Cp’,Th(OCH,), 4[Cp’2Th(OCH,)]2PH

+

+ 8H2 (6)

bustion experiments indicate that >95% of the evolved gas is hydrogen. There is no evidence for PH3 formation in the N M R experiments. In the case of the Cp’,U(CH,),/H2/P(OCH3), system, monitoring of the reaction by ‘H N M R failed to reveal any intermediates. Indeed, these spectral studies indicated that even detectable quantities of (Cp’,UH2), were not present-only starting materials and products. In contrast, the kinetically slower Cp’,Th(CH3),/H2/P(OCH,), system reveals a variety of intermediates when monitored by IH and 31PN M R . In N M R tube reactions of (Cp’,ThH2), and P(OCH,),, the hydride (Cp’,ThH,), is observed throughout most of the reaction, and in the initial stages (within 1 h) six OCH, resonances are evident in the * H N M R spectrum. At 109.16 MHz, eight singlets are observed in the 31P{1H) spectrum within 1 h, and all split into doublets, with lJp-H ranging from 97 to 119 H z in the coupled spectrum. No 3Jp-H couplings indicative of P-OCH, species ( J = 7-14 Hz2’) are detected. Clearly, cleavage of the P-OCH, bonds and the formation of >P-H groups take place in the initial stages of the reaction. Survey N M R tube reactions indicate that the Cp’2U(CH3)2/H2 reagent also reacts with P(O-i-C3H7),,but at a considerably slower rate than with P(OCH3)3. The nature of the products appears to be the same as in the trimethyl phosphite The Cp’,U(CH,),/H, system also reacts with P(C,H,)(OCH,), and P(C,H,),(OCH,). In the former case, the preliminary ‘H N M R data suggest the formation of a >P-C2H5-containing product and the uranium bis(methoxide) (7).35bIn addition, some 5 is also observed, suggesting possible P-C,H, hydrogenolysis. Curiously, IH N M R spectra of the second system reveal only Cp’2U(OCH3)2, (Cp’,UH,),, and (Cp’2UH),;11 the fate of the phosphorus-containing starting material is still under investigation. Further studies of these reactions are in progress.

Discussion This study reveals an unprecedented reaction pattern for an organo-d- or -f-element hydride in which a phosphite alkoxide functionality and the metal hydride ligand undergo rapid, quantitative transposition. Although the greater reactivity of trialkyl phosphite ligands over that of trialkylphosphine ligands is well documented,2f+10the bulk of this chemistry (involving transi(35) (a) NMR tube reactions under excess H, employing 0.4 equiv of P(O-i-C,H,), per equiv of Cp’,U(CH,), exhibited ‘H resonances after 14 h assignable to Cp’2U(O-i-C,H7)2[6 -0.555 (s, 30 H, Cp’), 1.19 (d, 12 H, J = 5.86 Hz, CH(CH3)2), 22.95 (septet, 2 H, J = 5.86 Hz, CH(CH,),)], resonances due to (CP’,,UH~)~,’’ and signals at 6 -3.6 (s) and +50.9 (broad, s, line width = 20 Hz) in the correct relative intensities for a (Cp’,U[OCH(CH3)2])2PH complex. (b) NMR tube reactions involving P(C,H,)(OCH,), show signals attributable to Cp’,U(OCH,), as well as singlets at 6 -3.0 (s, 60 H, Cp’?) and +75.5 (s, 6 H, OCH,?). The bis(methoxide) signals decrease at long (>50 h) reaction times. Although several small signals can be assigned to the ethyl group of a [Cp’,U(OCH3)]2PCH2CH3complex, infrared spectra also reveal a P-H stretching mode at 2192 cm-’.

tion-metal complexes) involves Arbuzov-like phosphonato products (3) in which R - 0 bond scission occurs. Reactions involving transition-metal-induced P-0 bond cleavage are rare and, to our knowledge, have only been identified in the case of an oxophilic titanium complex (eq 7)36or pyrolysis of a trimethyl phosphite 45 h

Cp2TiC12 + 2(CF3)2POP(CF3)2 2(CF3)2PC1 + Cp2Ti[OP(CF3)212 (7) cluster c ~ m p o u n d . ~ Rather, ’ the closest analogy to the present chemistry may be the single, brief report that LiA1H4 will dealkoxylate dialkyl alkylphosphonites and alkyl dialkylphosphinites as shown in eq 8 and 9.38 An extrapolation to trialkyl phosphites

is not unreasonable, and the hydridic, oxophilic character of organoactinide hydrides is well established.3J1~16~24a~39~40 The phosphorus-containing products of the present chemistry are binuclear p-PH (phosphinidene) complexes. As already noted, the only other well-characterized p2-phosphinidene complex is [CpMn(C0)2]2PC6H5 ( ll).,’ However, polynuclear p3-PR and p4-PR cluster compounds are far more common.41 The complex CrCo2(CO)I l(p3-PH) is the only other well-characterized pL,-PH compound.42

Acknowledgment. This research was supported by the National Science Foundation under Grants CHE-8009060 and CHE8306255. We thank W. R. Grace and Co. for gifts of desiccants. Registrv No. 5. 89579-17-9:, 6., 89596-62-3: 7. 89579-18-0: 8. 8957919-1;%(OkH,),, ‘121-45-9; Cp,’U(CH,),, 67605-92-9; Cp,’Th(CH,),, 67506-90-5.

Supplementary Material Available: Anisotropic thermal parameters and intra-(CH3)5C5metrical parameters for the nonhydrogen atoms of 5 , crystal structure analysis report, and structure factor tables (16 pages). Ordering information is given on any current masthead page. (36) Reagen, W. J.; Burg, A. B. Inorg. Nucl. Chem. Lett. 1971, 7 , 741-743. (37) Orpen, A. G.; Sheldrick, G. M. Acta Crystallogr., Sect. B 1978, 348, 1992-1 994. (38) Sander, M. Chem. Ber. 1960, 93, 1220-1230. (39) (a) Fagan, P. J.; Moloy, K. G.; Marks, T. J. J . A m . Chem. SOC.1981, 103,6959-6962. (b) Katahira, D. A.; Moloy, K. G.; Marks, T. J. ’Advances in Catalytic Chemistry 11”, in press. (c) Katahira, D. A,; Moloy, K. G.; Marks, T. J. Organometallics 1982, 1, 1723-1726. (d) Moloy, K. G.; Marks, T. J., submitted for publication. (40) (a) Fagan, P. J.; Maatta, E. A,; Marks, T. J. ACS Symp. Ser. 1981, No. 152, 53-78. (b) Fagan, P. J.f Manriquez, J. M.; Marks, T. J.; Day, V. W.; Vollmer, S . H.; Day, C. S . J . A m . Chem. Soc. 1980, 102, 5393-5396. (41) (a) Schneider, J.; Zsolnai, L.; Huttner, G. Chem. Ber. 1982, 115, 989-1003 and references therein. (b) Demarlin, F.; Monassero, M.; Sansoni, M.; Garlaschelli, L.; Sartorelli, U. J . Organornet. Chem. 1981, 204, C l W 1 2 . (c) Natarajan, K.; Zsolnai, L.; Huttner, G. Ibid. 1981, 220, 365-381. (d) Ryan, R. C.; Dahl, L. F. J . Am. Chem. SOC.1975, 97, 6904-6906. (e) Natarajan, K.; Zsolnai, L.; Huttner, G. J. Orgunomet. Chem. 1981, 209, 85-99. (f) Beurich, V. H.; Richter, F.; Vahrenkamp, H. Acta Crystullogr., Sect. B 1982,38B, 3012-3016. (9) Richter, F.; Beurich, V. H.; Varenkamp, H. J . Orgunomet. Chem. 1979, 166, C5-C8. (h) Bartsch, R.; Heitkamp, S.; Morton, S.; Stelzer, 0.Ibid.1981, 222, 263-273. (i) Huttner, G.; Mohr, G.; Friedrich, P.; Schmid, H. G. Ibid. 1978, 160, 59-66. 6) Huttner, G.; Schneider, J.; Mohr, G.; Seyert, J. V. Ibid. 1980, 191, 161-169. (k) Mays, M. J.; Raithby, P. R.; Taylor, P. L.; Henrick, K. Ibid. 1982, 224, C45-C48. (I) Bartsch, R.; Hietkamp, S; Morton, S.;Steltzer, 0. Ibid. 1982, 222, 263-273. (m) Natarajan, K.; Scheidsteger, 0.;Huttner, G. Ibid. 1981, 221, 301-308. (n) Huttner, G.; Frank, A,; Mohr, G. Z . Naturforsch., B: Anorg. Chem. Org. Chem. 1976, B31, 1161-1 165. (0)Huttner, G.; Mohr, G.; Frank, A. Angew. Chem., In?. Ed. Engl. 1976, 15, 682-683. (p) Vahrenkamp, H.; Wolters, D. J . Organomet. Chem. 1982, 224, C17-C20. (9) Field, J. S.; Haines, R. J.; Smit, D. N. Ibid. 1982, 224, C49-C52. (r) Maclaughlin, S. A,; Carty, A. J.; Taylor, N. Can. J . Chem. 1982, 60, 87-90. (42) Austin, R. G.; Urry, G. Inorg. Chem. 1977, 16, 3359-3360.